NZ522441A - A video projection system having a rotary disk to scan the images onto the screen - Google Patents

Abstract

A video projection system (30) comprises means (36,46) for generating a colour light bundle coloured according to a video signal and means (31,35) for line scanning the bundle onto a screen (48) thereby producing images on the screen (48), the system (30) also includes a disc (31) adapted to rotate on an axis (32) extending through a centre of the disc (31), the system also includes means for enlarging the horizontal projection angle, wherein the disc (31) carries a plurality of light guiding devices (35) extending radially of the disc (31) and spaced one from another in an angular direction in the plane of the disc (31) and each device (35) extending at an angle to the plane of the disc (31) in a corresponding plane perpendicular to the plane of the disc (31) so that each device (35) projects a corresponding one of the lines scanning a video image on to the screen (48) and wherein the means for enlarging the horizontal projection angle include a combination of mirrors.

Description

<div class="application article clearfix" id="description"> <p class="printTableText" lang="en">5224 41 <br><br> l <br><br> A VIDEO PROJECTION SYSTEM <br><br> This invention relates to a video projection system. <br><br> 5 <br><br> In WO 95/03675 there is disclosed a video projection system comprising means for generating a colour light bundle coloured according to a video signal and 'means for line scanning the bundle onto a screen thereby, producing images 10 on the screen. <br><br> The system includes a disc which is adapted to rotate on an axis extending through a centre of the disc and at right angles to the plane of the disc, the disc having a series of plane 15 mirror facets extending circumferentially of the disc on a circumferential surface thereof, and a plane mirror adapted to pivot relative to an axis extending through the plane of the mirror and parallel to a diameter of the disc for receiving the bundle of light reflected from successive mirror facets during 20 rotation of the disc. <br><br> A problem with such a known video projection system is that the functions required of the pivotable plane mirror are very demanding and are not achievable with today's technology and 25 are unlikely to be achieved in the near future. <br><br> 1 NT^L^|CT^AL PROpERyy OFF ICS OF l\J 2 <br><br> "4 FES <br><br> 2 <br><br> It is the object of the present invention to overcome or substantially ameliorate at least one of the above disadvantages. <br><br> Accordingly, the present invention provides a video projection system comprising means for generating a colour light bundle coloured according to a video signal and means for line scanning the bundle onto a screen thereby producing images on the screen, the system also including a disc adapted to rotate on an axis extending through a centre of the disc, the system also including means for enlarging the horizontal projection angle, wherein the disc carries a plurality of light guiding devices extending radially of the disc and spaced from one another in an angular direction in the plane of the disc and each device extending at an angle to the plane of the disc in a corresponding plane perpendicular to the plane of the disc so that each device projects a corresponding one of the lines scanning a video image onto the screen and wherein the means for enlarging the horizontal projection angle include a combination of mirrors. <br><br> A preferred form of the present invention will now be described by way of example with reference to the accompanying drawings, wherein: <br><br> Figure 1 is a diagrammatic elevation demonstrating the concept of a video projection system in accordance with the present invention, <br><br> Figure 2 is a diagrammatic perspective view of the arrangement shown in Figure 1, Figure 3 is a diagrammatic elevation of a preferred embodiment of a video projection system in accordance with the present invention, <br><br> Figure 4 is a diagrammatic perspective view of the embodiment shown in Figure 3, Figure 5 is a diagrammatic elevation of another embodiment of a video projection system in accordance with the present invention, <br><br> INTELLECTUAL PROPERTY OFFICE OF NZ <br><br> - FEB im <br><br> RECEIVED <br><br> [R:\LIBLL] 15249.doc:gxt <br><br> WO 01/86966 <br><br> PCT/GB01/01800 <br><br> 3 <br><br> Figure 6 is a diagrammatic perspective view of the embodiment shown in Figure 5, <br><br> Figure 7 is a diagrammatic elevation of another embodiment of 5 a video projection system in accordance with the present invention, and <br><br> Figure 8 is a diagrammatic perspective view of the embodiment shown in Figure 7. <br><br> 10 <br><br> Referring now to Figures 1 and 2 of the drawings, which are diagrammatic conceptual representations, a video projection system 10 in accordance with the present invention comprises a disc 11 which is adapted to rotate on an axis 12 extending 15 through a centre of the disc 11 and at right angles of the plane of the disc. In this regard, the disc 11 is secured on a shaft 13 of a motor 14, the central longitudinal axis of the shaft 13 being coaxial with the axis 12. The disc 11 has mounted thereon a plurality of light guiding devices 15 extending 20 radially of the disc 11 in a margin extending circumferentially of the disc 11. The devices 15 axe arranged in groups 16 and the devices 15 in each group 16 are stacked one above another in respective radial planes of the disc 11 and extend at specified angles relative to the plane of the disc 11 in the 25 respective planes. The planes containing the groups 16 are angular spaced equi-distant one from another throughout a 360 degrees sweep of the plane of the disc 11. <br><br> The system 10 includes a plurality of component groups 17 30 each comprising three laser light sources 18, 19 and 20 for providing respectively the colours red, green and blue of a <br><br> WO 01/86966 PCT/GB01/01800 <br><br> 4 <br><br> video signal, corresponding modulators 21, 22 and 23 for modulating the intensity of the light bundles which issue from the light sources 18 to 20, a plane mirror 24 and two plane dichroic mirrors 25 and 26 for combining into a single light 5 bundle, the modulated light bundles and a mirror 27 for reflecting the combined light bundles. The array of mirrors 27 corresponding to the respective component groups 17 are stacked at a location relative to the disc 11 spaced inwardly of the margin of the disc 11 containing the groups 16 of light 10 guiding devices. <br><br> The system 10 also includes an optical system, shown generally at 28, for enlarging the horizontal projection angle, the optical system 28 being located opposite the array of 15 mirrors 27 and adjacent the periphery of the disc 11, and a screen 29. <br><br> The system 10 may be adapted for scanning 625 lines on the screen 28 for each 1/25 of a second, where 25 is the number 20 of images per second contained in the video signal. In order to achieve this, 125 groups 16 each comprising 5 light guiding devices 15 are located on the disc 11 (although only 25 groups 16 are shown in Figure 2 for clarity), each group 16 being positioned at an angle of 2.88 degrees in the plane of the disc 25 11 from an adjacent group 16 and the angular positioning of the devices 15 in their respective radial planes relative to the plane of the disc 11 is calculated so as to project light at an angle relative to the plane of the disc 11 according to the formula:- <br><br> 30 <br><br> +9 - (N-l) x JL8 degrees. <br><br> 624 <br><br> WO 01/86966 <br><br> PCT7GB01/01800 <br><br> 5 <br><br> where N is the number positioning of a light guiding device 15 in the range 1 to 625 starting from an uppermost guide 15. <br><br> 5 The light guiding devices 15 each of which may be a light rod, a waveguide, a cavity, a lens or any combination thereof, in effect, provide a helical formation of 625 devices 15 during 5 consecutive revolutions of the disc 11. The speed of the motor 14 is 125 revolutions per second. <br><br> 10 <br><br> Since there are 5 light guiding devices 15 in each group 16, there are 5 component groups 17, each associated with a corresponding on,e of the 5 devices 15 of each group 16. The component groups 17 control operation of the light guiding 15 devices 15 as each of the devices 15 moves between the mirrors 27 and the optical system 28, signals switching from one group 17 to another after each revolution of the disc 11 until five revolutions of the disc 11 have been completed, when the sequence is repeated. <br><br> 20 <br><br> It will be appreciated that instead of there being 5 component groups 17, only one component group 17 may be provided which would direct the combined light bundle to the appropriate layer of light guiding devices 15. <br><br> 25 <br><br> Referring now to Figures 3 and 4 of the drawings, there is shown a preferred embodiment of a video projection system 30 comprising a disc 31 which is rotatable, on an axis 32 extending through a centre thereof, by means of a motor 33. 30 The disc 31 is provided with a circumferential margin 34 of increased cross sectional dimension and the margin 34 is <br><br> WO 01/86966 <br><br> PCT/GBO1/01800 <br><br> 6 <br><br> provided with 625 light guiding devices 35 in the form of cavities enveloped in a laser reflecting material, each being curved in a plane perpendicular to the plane of the disc so as to project light at an angle in accordance with the formula 5 stated above, each extending radially of the disc 31 and each extending at an angle of 0.576 degrees one to another in the plane of the disc 31. The angular relationship of the light guiding devices 35 one to another in their respective planes perpendicular to the plane of the disc 31 is such that the 10 sweep of the devices 35 through 360 degrees of the circumference of the disc 31 is helical in configuration. <br><br> The system 30 includes a component group 36 comprising three laser light sources 37, 38 and 39 for providing 15 respectively the colours red, green and blue of a colour video signal, corresponding modulators 40, 41 and 42 for modulating the intensity of the light bundles which issue from the light sources 37 to 39, a plane mirror 43 and plane dichroic mirrors 44 and 45 for combining into a single light 20 bundle, the modulated light bundles and a mirror 46 for reflecting the combined light bundles. <br><br> The system 30 also includes an optical system, shown generally at 47, for enlarging the horizontal projection angle 25 the optical system 30 being located opposite the mirror 46 and adjacent the periphery of the disc 31, and a screen 48. <br><br> In operation, the motor 33 is arranged to rotate the disc 31 at 25 revolutions per second and the component group 36 30 operates so that a bundle of light reflected by the mirror 46 is directed through the light guiding devices 35 as they pass <br><br> WO 01/86966 <br><br> PCT/GB01/01800 <br><br> 7 <br><br> successively between the mirror 46 and the optical system 47. The spiral configuration of the light guiding devices 35 ensures that screen 48 is scanned by 625 lines per revolution of the disc 31 and the speed of the rotating disc 31 ensures that the 5 images received on the screen 48 match the number of images per second contained in the video signal. <br><br> Referring now to Figures 5 and 6 of the drawings, there is shown an embodiment of a video projection system 50 which is 10 similar to the system 30 shown in Figures 3 and 4 and same reference numerals are incorporated in Figures 5 and 6 for the same components which are shown in Figures 3 and 4. <br><br> In the system 50, the motor 33 is located above the disc 31 15 and the components of one possible embodiment of the optical system 47 are shown in detail. More particularly, the optical system 47 comprises a toroidal mirror 51, this facing away from the disc 31 and having a slot 52, a concave spherical mirror 53 facing the toroidal mirror 51 and a concave 20 cylindrical mirror 54 facing the toroidal mirror 51. <br><br> The arrangement is such that, in operation and while disc 31 rotates, a light bundle directed through the light guiding devices 35 passes successively through the slot 52 to the 25 concave mirror 53 where it is reflected back onto the toroidal mirror 51. At the toroidal mirror 51 the light bundle is reflected onto the concave cylindrical mirror 54 where it is again reflected and passes under the disc 31 and is received at the screen 48 as a spot substantially 2.5 mm in diameter. <br><br> 30 <br><br> WO 01/86966 PCT/GB01/01800 <br><br> 8 <br><br> As each light guiding device 35 moves 0.576 degrees in front of the mirror 46, the light projected by each light guiding device 35 moves from left to right of the screen 48 along the line of the video image corresponding to the particular light guiding 5 device. <br><br> In an alternative arrangement, the toroidal mirror 51 may be located between the mirror 46 and the margin 34 of the disc 31. <br><br> 10 <br><br> Referring now to Figures 7 and 8 of the drawings, there is shown an embodiment of a video projection system 55 which is similar to the system 30 shown in Figures 3 and 4 and the same reference numerals are incorporated in Figures 7 and 8 15 for the same components which are shown in Figures 3 and 4. <br><br> In the system 55 the components of another possible embodiment of the optical system 47 are shown in more detail. More particularly, the optical system comprises a plane mirror 20 56, this facing away from the disc 31 and having a slot 57, a concave spherical mirror 58 facing the plane mirror 56 and the reflective surface of the plane mirror 56 being at an angle of 45 degrees to the focal plane of the concave spherical mirror 58, a toroidal mirror 59 being at an angle of 45 degrees to reflective 25 light from the plane mirror 56 and a concave cylindrical mirror 60 facing the toroidal mirror 59. <br><br> The arrangement is such that, in operation, and while disc 31 rotates, a light bundle directed through the light guiding 30 devices 35 passes successively through the slot 57 to the concave mirror 58, where it is reflected back onto the plane <br><br> WO 01/86966 <br><br> PCT/GB01/01800 <br><br> 9 <br><br> mirror 56. At the plane mirror 56 the light bundle is reflected onto the toroidal mirror 59 where it is reflected on to the concave cylindrical mirror 60 where it is again reflected and passes under the disc 31 and is received at the screen 48 as a 5 spot substantially 2.5 mm in diameter. <br><br> It will be appreciated that a video projection system in accordance with the present invention may be adjusted to scan a different number of lines per image than 625. For example, 10 if the number of lines to be scanned is 525, the disc will be provided with a corresponding number of light guiding devices. <br><br> It will also be appreciated that, instead of providing modulators for modulating the intensity of light issuing from 15 the light sources, the light sources may be modulated by directly modulating the electrical input currents to the light sources. <br><br> Furthermore, it will be appreciated that the term "mirror" may 20 include a block of laser reflective material, such as magnesium oxide. <br><br></p> </div>

Claims (9)

<div class="application article clearfix printTableText" id="claims"> <p lang="en"> 10<br><br> The claims defining the invention are as follows:<br><br>

1. A video projection system comprising means for generating a colour light bundle coloured according to a video signal and means for line scanning the bundle onto a screen thereby producing images on the screen, the system also including a disc adapted<br><br> 5 to rotate on an axis extending through a centre of the disc, the system also including means for enlarging the horizontal projection angle, wherein the disc carries a plurality of light guiding devices extending radially of the disc and spaced from one another in an angular direction in the plane of the disc and each device extending at an angle to the plane of the disc in a corresponding plane perpendicular to the plane of the disc so that<br><br> 10 each device projects a corresponding one of the lines scanning a video image onto the screen and wherein the means for enlarging the horizontal projection angle include a combination of mirrors.<br><br>

2. A video projection system as claimed in claim 1 wherein the combination of mirrors comprise a concave spherical mirror for reflecting the light bundle from the<br><br> 15 scanning means, a toroidal mirror for reflecting the light bundle from the concave spherical mirror and a concave cylindrical mirror for reflecting the light bundle from the toroidal mirror to the screen.<br><br>

3. A video projection system as claimed in claim 2 wherein the toroidal mirror is provided with a slot which is arranged so that the light bundle incident on the concave<br><br> 20 spherical mirror passes through the slot.<br><br>

4. A video projection system as claimed in claim 1 wherein the combination of mirrors comprise a concave spherical mirror for reflecting the light bundle from the scanning means, a plane mirror for reflecting the light bundle from the concave spherical mirror, a toroidal mirror for reflecting the light bundle from the plane mirror and a<br><br> 25 concave cylindrical mirror for reflecting the light bundle from the toroidal mirror to the screen.<br><br>

5. A video projection system as claimed in claim 4 wherein the plane mirror is provided with a slot which is arranged so that the light bundle incident on the concave spherical mirror passes through the slot.<br><br> 30

6. A video projection system as claimed in claim 2 or claim 3 wherein the toroidal mirror is located between the light bundle guiding devices and the mirror.<br><br> ramlcTUAi: propIrty<br><br> I OFFICE OF HZ<br><br> I - FEB 2CQA<br><br> [R:\LIBLL] 15249.doc:gxt I RECEIVED<br><br> 11<br><br>

7. A video projection system as claimed in any one of the preceding claims wherein the devices are arranged in a single helical configuration.<br><br>

8. A video projection system as claimed in any one of the preceding claims wherein the means for generating the coloured light bundle include a number of dichroid mirrors used to combine a number of light bundles into one coloured light bundle.<br><br>

9. A video projection system substantially as hereinbefore described with reference to Figs 1 and 2; Figs 3 and 4; Figs 5 and 6; or Figs 7 and 8 of the accompanying drawings.<br><br> Frederic Jean-Pierre Demole By the Attorneys for the Applicant<br><br> SPRUSON &amp; FERGUSON<br><br> Per:<br><br> [R:\LIBLL] 15249.doc:gxt<br><br> </p> </div>